WASTE HEAT ENGINE

Description

BACKGROUND OF THE INVENTION

Field of the Invention

[0001] This invention relates to steam engines and, more particularly, to a low pressure, low temperature self-starting steam engine that uses waste heat from an external source, and wherein the engine includes a radial arrangement of cylinders with reciprocating pistons for driving rotation of a crankshaft.

Discussion of the Related Art

[0002] The need to operate at higher temperatures and pressures results in considerable heat loss in conventional steam engines. And, while steam engines are typically larger in size and less efficient than internal combustion engines and diesel engines, (unless operating at high temperatures and pressures) the loss of heat in all types of engines significantly reduces engine efficiency. Accordingly, the ability to harness heat loss during engine operation is highly beneficial and can improve overall engine efficiency. Moreover, waste heat from normal engine operation, as well as other heat sources, can be used in alternative engine designs for generating power. For instance, the energy from waste heat in the operation of an internal combustion engine, refuse burner, or solar energy collector can be used in the operation of an alternative engine for operating an electric power generator.

Objects and Advantages of the Invention

[0003] Considering the foregoing, it is a primary object of the present invention to provide a steam engine that operates on low pressure, low temperature steam with the use of waste heat from an external heat source, such as an internal combustion engine, a refuse (e.g. garbage) burner, or a solar heat collector.

[0004] If is a further object of the present invention to provide a steam engine that operates on waste heat from an external heat source, and wherein the engine is self-starting.

[0005] It is still a further object of the present invention to provide a steam engine having a radial piston configuration, and wherein the engine operates on low pressure, low temperature steam, with an operating pressure of 2 psi to over 200 psi.

[0006] It is still a further object of the present invention to provide a steam engine that operates in a low temperature range of 225° F to 600° F.

[0007] It is still a further object of the present invention to provide a steam engine that operates on waste heat from an external heat source, and wherein the engine is useful in the generation of electric power.

[0008] It is yet a further object of the present invention to provide a steam engine that operates on low pressure, low temperature steam with the use of waste heat, and wherein the engine is scalable to increase or decrease size and output as needed.

[0009] These and other objects and advantages of the present invention are more readily apparent with reference to the detailed description and accompanying drawings.

Summary of the Invention

[0010] The present invention is directed to an engine that includes a radial arrangement of cylinders each having a reciprocating piston with a piston head and a connecting rod pivotally linked to the piston head at an upper end. A lower end of each connecting rod is pivotally linked to a crank disk that is rotatably fitted on a crank arm of a crankshaft. Steam intake valves at each cylinder are momentarily opened by a bearing cam roller that is moved in a circular path by rotation of the crank disk to sequentially engage spring urged cam followers on inboard ends of radially extending valve stems. Low pressure steam or gas is injected into the top of each cylinder, as the intake valves are opened in sequence, thereby forcing the piston in each cylinder through a power stroke to move the crank disk and turn the crankshaft. Angular displacement of each connecting rod through the return stroke of the piston urges an exhaust reed valve on the piston head to an open position, thereby releasing exhaust steam to a condenser chamber. The engine is self-starting and operates in a low pressure, low temperature range, using waste heat from an external source, such as exhaust from an internal combustion engine, burning of refuse (e.g. garbage or other solid waste material) or solar heat.

Brief Description of the Drawings

[0011] For a fuller understanding of the nature of the present invention, reference should be made to the following detailed description taken in conjunction with the accompanying drawings in which:

Figure 1 is an elevational view, shown in cross-section, of the waste heat engine;

Figure 2 is an isolated cross-sectional view taken from the area indicated as 2 in Figure 1;

Figure 3 is an isolated top plan view showing a spider bearing (i.e., crank disk) and a piston and cylinder arrangement of the waste heat engine;

Figure 4 is an isolated top plan view in cross-section, showing a steam intake valve and intake valve control assembly for controlling a low pressure steam or gas injection into each of the cylinders of the waste heat engine;

Figure 5A is an isolated top plan view, shown in cross-section, taken from the area indicated as 5A in Figure 4 showing a bearing cam roller positioned in contact with one cam follower on an inboard and of a valve stem, thereby urging the intake valve on the opposite end of the valve stem to an open position;

Figure 5B is the same isolated cross-sectional view as shown in Figure 5A, with the bearing cam roller shown in simultaneous contact with two adjacently positioned cam followers on inboard ends of valve stems that are spaced radially about a cam follower guide ring surrounding the rotational path of the bearing cam roller;

Figure 6 is an isolated view, shown in cross-section, taken from the area indicated as 6 in Figure 4, showing an intake valve at one of the cylinders in an open position to thereby allow injection of low pressure steam or gas into the top of the cylinder;

Figure 7 is an isolated view, shown in cross-section, showing the intake valve of Figure 6 in a closed position;

Figures 8A-8D illustrate reciprocating movement of a piston within a cylinder from a top dead center position through an exhaust stroke;

Figure 9 is a top plan view, in partial cross-section, taken along the plane of a line indicated as 9-9 in Figure 1; and

Figure 10, is a perspective view of the exterior of the waste heat engine.

[0012] Like reference numerals refer to like parts throughout the several views of the drawings.

Detailed Description of the Preferred Embodiment

[0013] Referring to the several views of the drawings, and initially figures 1-3, the waste heat engine of the present invention is shown and is generally indicated as 10. An upper portion 12 of the engine 10 has a radial arrangement of cylinders 20. Low pressure (i.e., generally between 20 psi-200 psi), low temperature (i.e., generally between 225°F to 600°F) steam is generated using waste heat from an external heat source (not shown) such as an internal combustion engine, a refuse (e.g., garbage, waste material) burner, or a solar heat collector to generate seam. Water from a condenser 30 is heated in an external boiler (not shown), using the waste heat to produce steam. The low pressure, low temperature steam is directed through a main line (not shown) that connects to a steam inlet port 19 on a generally circular manifold 18 that is supported on the upper portion 12 of the engine 10. Manifold 18 is structured and disposed to equally distribute the low pressure to intake valves at each cylinder 20. A central portion 14 of the engine 10 includes the condenser 30 including a chamber 32 that is surrounded by a folded star-shaped condenser wall 34. A lower portion 16 of the engine 10 contains a blower 40 with a fan blade arrangement 42 that directs intake air up through cooling ports 44 at the bottom of the condenser. The blower is driven by rotation of the engine crankshaft 24. The cooling air passes through air transfer ducts 46 that surround the exterior of the folded wall structure 34 of the condenser 30 and exits out from blower exhaust ports 48, thereby cooling the exhaust steam within the condenser chamber 32. A fluid pump 36 on the engine is driven by rotation of the crankshaft 24 via a belt drive 37. The pump 36 returns liquid condensate collected in the bottom of the condenser chamber 32 to the steam generating source (e.g. a boiler), wherein waste heat is again used for generating the low pressure, low temperature steam used in the operation of the engine 10.

[0014] Referring to figure 3, each cylinder 20 in the radial arrangement includes a reciprocating piston assembly 50, including a piston head 52 that moves in a reciprocating motion within the cylinder 20 through a full piston stroke. A connecting rod 54 is pivotally linked to the piston head 52 and a central crank disk or spider bearing 60. More specifically, the connecting rod 54 of each piston assembly 50 is pivotally linked at an upper end to the piston head 52 with a wrist pin bearing 56. Similarly, a lower end of the connecting rod 54 is pivotally linked to the crank disk 60 with a wrist pin bearing 58. The crank disk 60 is eccentrically fixed to the crankshaft 24. More particularly, a crank arm on the crankshaft 24 is rotatably fitted to the center of the crank disk 60 so that the center of the crank disk 60 is offset relative to the longitudinal axis of the crankshaft 24. As steam is injected into the top of each cylinder 20 and the piston 52 is moved downwardly within the cylinder, the connecting rod 54 pivots and transmits a force on the crank disk 60 that is offset relative to the longitudinal central axis on the crankshaft 24, thereby causing the crank disk 60 to move in an orbiting motion around the central longitudinal axis of the crankshaft 24, as the crankshaft is turned. Movement on the crank disk 60 about a full orbital motion, with a complete turn of the crankshaft 24, causes the lower pivoting end of each connecting rod 54 to travel through a circular path, as indicated by the arrow in Figures 8A-8D. Restrictor pins 64 associated with each cylinder are fixed to the crank disk 60 and are specifically spaced and arranged relative to one another so as to abut against ears 59 on the lower end of the connecting rod 54 to limit angular deflection of each connecting rod 54.

[0015] The steam injection valve assembly is shown in figures 4-7. Referring to figures 4, 6 and 7, a valve head 70 is located at the top of each cylinder. The valve head includes a valve seat 72 and a valve cap 74. A poppet valve 76 moves in relation to the valve seat 72, between an open position (see figure 6) and a closed position (see figure 7). Steam from the manifold 18 is directed into a valve chamber 78 within the valve head 70 and, when the poppet valve 76 is opened, the steam is injected through a port 80 and into the top of the cylinder 20. The valve chamber 78 is surrounded by an insulating material 82 to maintain the temperature of the steam within the chamber 78 when the valve 76 is closed. An elongate valve stem 84 extends from the poppet valve 76 inwardly towards a cam follower guide ring 86, as seen in figures 4-5B. Referring to figure 4, it is seen that the valve stems 84 are arranged in the same radial configuration as the cylinders 20, with the valve stems 84 extending from the valve heads 70 at the top of the cylinders and inwardly to the cam follower guide ring 86. The valve stems 84 each extend through a valve stem tube 88 that is fitted to a seal gland 90 at the base of the valve head 70. A seal packing 91 and an O-ring 92 help to discourage escape of the steam from the valve head 70. An opposite inboard end of the valve stem tube 88 is fitted to a attachment tube 94 that extends into the cam follower guide ring 86. Cam followers 96 fitted to the end of each valve stem 84 are positioned to extend radially inward into an area 87 within the cam follower guide ring 86 at equally spaced intervals relative to the inner circumference of the guide ring. The cam followers 96 are urged inwardly towards the area within the guide ring by return springs 97 within the respective attachment tubes 94.

[0016] A ball bearing cam roller 100 is connected to the top of the spider bearing and/or a crank throw linked to the crankshaft. The cam roller 100 orbits about a circular path within the interior area 87 surrounded by the cam follower guide ring 86. A cam counter-balance weight 102 stabilizes movement of the cam roller 100 as it moves in the eccentric path within the cam follower guide ring 86. The cam roller 100 is specifically sized, structured and disposed for contacting the cam followers 96 on the ends of the valve stems 84. More particularly, as the cam roller 100 moves about the orbital path, it is in contact, at all times with at least one cam follower 96. Movement of the pistons 50 to drive the spider bearing 60 and the crankshaft 24 serves to also move the cam roller 100 in its circular path. As the cam roller 100 contacts each cam follower 96, the associated valve stem 84 is urged axially outward to open the respective poppet valve 76, thereby injecting steam into the associated cylinder 20. As previously noted, the cam roller 100 is always in contact with at least one cam follower 96, so that at any given moment, steam is being injected into at least one cylinder. As the cam roller 100 moves away from one cam follower 96, it simultaneously contacts the next cam follower 96, so that there is an overlap period of steam injection into two adjacent cylinders.

[0017] Referring to figures 8A-8D, each piston assembly 50 within a respective cylinder 20 includes piston head 52 with a seal 53 that engages the inner wall surfaces of the cylinder. As the connecting rod 54 is angularly displaced during the exhaust stroke (see figure 8D), a valve lifter 110 on the top end of the connecting rod 54, defined by a generally triangular formation with an apex, hits an exhaust reed valve 120 on the top of the piston head 52. The valve lifter 110 urges the exhaust reed valve 120 from a relaxed position to a raised position, against the force of the spring action of the reed valve flap which is secured at one end by fastener 122 to the piston head 52. With the reed valve flap 120 in the open position, as seen in figure 8D, the low pressure steam in the upper portion of the cylinder is released through ports 130 formed through the piston head 52, allowing the steam to exhaust into a condenser chamber 32 of the engine 10 as the piston 50 returns to the top dead center position.

[0018] Driven rotation of the crankshaft 24, by forced movement of the pistons 50 within the cylinders 20, serves to operate an alternator 140 (or other electric power generator device) via a belt drive or similar linkage between the crankshaft 24 and the alternator 140. Accordingly, operation of the engine 10 serves to generate electric power.

[0019] It is particularly desirable that engine 10 be self-starting. In one preferred embodiment, the radial arrangement of cylinders 20 includes a total of six cylinders, as seen in figures 3. The radial arrangement of six cylinders is particularly beneficial for self-starting and allows for two adjacently positioned cylinders to have their intake valves open during an overlap period so that, at any given moment, two pistons are under force of steam pressure, in a downward power stroke to drive movement of the crank disk and rotation of the crankshaft.

[0020] While the present invention has been shown and described in accordance with a preferred and practical embodiment, it is recognized that departures from the instant disclosure are fully contemplated within the spirit and scope of the invention as defined in the claims which follow.

Claims

1. An engine comprising:

a plurality of cylinders arranged in a radial configuration surrounding a central area, and each of said cylinders having a reciprocating piston assembly that is operably moveable through a downward power stroke and an upward returning exhaust stroke, and each piston assembly including a piston moveably disposed within the cylinder and a connecting rod pivotally linked at a first end to said piston and extending from the cylinder and terminating at an opposite second end within the central area;

a crankshaft extending axially through said engine along a longitudinal central rotational axis and including an upper end portion and a lower end portion and said crankshaft being rotatable about said central longitudinal axis;

a crank disk drivingly linked to the upper end portion of the crankshaft and moveable about a central pivot axis of said crank disk that is offset relative to the central rotational axis of the crankshaft so that said crank disk moves in an orbital motion about said central rotational axis as the crankshaft rotates;

a steam distribution assembly including a manifold for receiving a supply of steam and a plurality of steam inlet valve assemblies connected to said manifold for controllably injecting pressurized steam into the cylinders, and each of said plurality of steam inlet valve assemblies including a steam inlet valve at each of said plurality of said cylinders, and said stem inlet valve at each cylinder including a valve member operable between an open position and a closed position relative to a valve seat, and an inlet port extending between the valve seat and an interior of the cylinder above the piston, and each of said steam inlet valves further including a valve stem extending from the valve member to an inboard end, and said inboard and having a spring urged cam follower fitted thereto;

a cam roller moveable about a circular path upon rotation of said crank disk and the crankshaft to sequentially engage the spring urged cam followers on the inboard ends of the valve stems and momentarily urge the valve member away from the valve seat, thereby opening the inlet valve and allowing injection of the steam into the cylinder in order to force the piston through the downward power stroke and move the crank disk in the orbital motion, thereby rotating the crankshaft;

a reed valve flap fastened to a top of the piston in each of said plurality of cylinders and defining an exhaust valve, and said reed valve flap being moveable between a closed position against the top of the piston and an open position defined by said reed valve flap at least partially lifted away from the top of the piston;

a valve lifter on each of said connecting rods, said valve lifter being structured and disposed to engage said reed valve flap as said piston approaches a top of the upward returning exhaust stroke, to thereby lift and open said reed valve flap and allow steam within a top portion of the cylinder to exhaust through the cylinder and into the central area;

a condenser including a condenser chamber communicating with the central area for receiving the exhaust steam;

a blower structured and disposed to direct a cooling airflow over an exterior surface of the condenser, thereby condensing the steam within the condenser into liquid;

a pump operably driven by rotation of said crankshaft for pumping the liquid from the condenser to an external steam generating source; and

an electric power generator device operably linked to the crankshaft and operated by rotation of the crankshaft to thereby produce electric power.

2. The engine as recited in claim 1 further comprising:

ear members protruding from opposite sides of each of said connecting rods on said opposite second end;

restrictor pins on said crank disk for engaging said ear members on the second end of the connecting rods for limiting angular deflection of each of said connecting rods during movement of said reciprocating piston assembly through the downward power stroke and the upward returning exhaust stroke.

3. The engine as recited in claim 1 further comprising;
a cam follower guide ring surrounding the central area and being structured and disposed for holding the spring urged cam followers in a radially spaced arrangement about the central area.

4. The engine as recited in claim 1 wherein said valve lifter includes a generally triangular formation on said first end of each of said connecting rods, and said generally triangular formation .including an apex for engaging the reed valve flap and moving the reed valve flap to the open position as said piston approaches a top of the upward returning exhaust stroke.

Ansprüche

1. Motor, der Folgendes aufweist:

eine Vielzahl von Zylindern, die in einer radialen Konfiguration angeordnet sind, die einen mittleren Bereich umgibt, und wobei jeder der Zylinder eine sich hin und her bewegende Kolbenanordnung hat, die betriebsmäßig über einen abwärts gerichteten Leistungshub und einen aufwärts gerichteten umgekehrten Auslasshub bewegbar ist, und wobei jede Kolbenanordnung einen Kolben aufweist, der bewegbar in dem Zylinder angeordnet ist und eine Pleuelstange, die schwenkbar an einem ersten Ende mit dem Kolben verbunden ist und sich von dem Zylinder erstreckt, und an einem gegenüberliegenden zweiten Ende in dem mittleren Bereich endet;

eine Kurbelwelle, die sich axial durch den Motor entlang einer mittigen Längsdrehachse erstreckt und einen oberen Endteil und einen unteren Endteil aufweist, und wobei die Kurbelwelle um die mittige Längsachse drehbar ist;

eine Kurbelscheibe, die treibend mit dem oberen Endteil der Kurbelwelle verbunden ist und um eine mittige Schwenkachse der Kurbelscheibe bewegbar ist, die relativ zur mittigen Drehachse der Kurbelwelle versetzt ist, so dass die Kurbelscheibe sich in einer Orbital- bzw. Umlaufbewegung um die mittige Drehachse bewegt, wenn sich die Kurbelwelle dreht;

eine Dampfverteilungsanordnung, die eine Sammelleitung aufweist, um eine Dampflieferung aufzunehmen, und eine Vielzahl von Dampfeinlassventilanordnungen, die mit der Sammelleitung verbunden sind, um in steuerbarer Weise unter Druck gesetzten Dampf in die Zylinder einzuspritzen, und wobei jede der Vielzahl von Dampfeinlassventilanordnungen ein Dampfeinlassventil an jedem der Vielzahl von Zylindern aufweist, und wobei das Dampfeinlassventil an jedem Zylinder ein Ventilglied aufweist, welches bezüglich eines Ventilsitzes zwischen einer offenen Position und einer geschlossenen Position betätigbar ist, und einen Einlassanschluss, der sich zwischen dem Ventilsitz und einem Innenraum des Zylinders über dem Kolben erstreckt, und wobei jedes der Dampfeinlassventile weiter einen Ventilschaft aufweist, der sich von dem Ventilglied zu einem innenbordliegenden Ende erstreckt, und wobei das innenbordliegende Ende eine dazu passende federgetriebene Nockenfolgevorrichtung hat;

eine Nockenrolle, die bei einer Drehung der Kurbelscheibe und der Kurbelwelle unreine kreisförmigen Pfad bewegbar ist, um sequentiell die federgetriebenen Nockenfolgevorrichtungen an den innenbordliegenden Enden der Ventilschäfte in Eingriff zu bringen und momentan das Ventilglied weg vom Ventilsitz zu drücken, wodurch das Einlassventil geöffnet wird und eine Einspritzung von Dampf in den Zylinder gestattet wird, um den Kolben über den abwärts gerichteten Leistungshub zu drücken und die Kurbelscheibe in der Orbitalbewegung zu bewegen, wodurch die Kurbelwelle gedreht wird;

eine Membranventilklappe, die an einem Oberteil des Kolbens in jedem der Vielzahl von Zylindern befestigt ist und ein Auslassventil definiert, und wobei die Membranventilklappe zwischen einer geschlossenen Position an dem Oberteil des Kolbens und einer offenen Position bewegbar ist, die dadurch definiert wird, dass die Membranventilklappe zumindest teilweise vom Oberteil des Kolbens abgehoben ist;

eine Ventilhubvorrichtung an jeder der Pleuelstangen, wobei die Ventilhubvorrichtung so strukturiert und angeordnet ist, dass sie mit der Membranventilklappe in Eingriff kommt, wenn der Kolben sich einem oberen Teil des aufwärts gerichteten umgekehrten Auslasshubes nähert, um dadurch die Membranventilklappe anzuheben und zu öffnen, und zu gestatten, dass Dampf innerhalb eines oberen Teils des Zylinders durch den Zylinder und in den mittleren Bereich austritt;

einen Kondensator, der eine Kondensatorkammer aufweist, die mit dem mittleren Bereich in Verbindung steht, um den austretenden Dampf aufzunehmen;

ein Gebläse, das so strukturiert und angeordnet ist, dass es einen kühlenden Luftflüss über eine Außenfläche des Kondensators leitet, wodurch der Dampf in dem Kondensator zu Flüssigkeit kondensiert;

eine Pumpe, die betriebsmäßig durch eine Drehung der Kurbelwelle angetrieben wird, um die Flüssigkeit vom Kondensator zu einer externen Dampferzeugungsquelle zu pumpen; und

eine Generatorvorrichtung für elektrische Leistung, die betriebsmäßig mit der Kurbelwelle verbunden ist und durch eine Drehung der Kurbelwelle betrieben wird, um dadurch elektrische Leistung zu erzeugen.

2. Motor nach Anspruch 1, der weiter Folgendes aufweist:

Ansatzglieder, die von gegenüberliegenden Seiten von jeder der Pleuelstangen an dem gegenüberliegenden zweiten Ende vorstehen;

Begrenzungsstifte an der Kurbelscheibe, um mit den Ansatzgliedern an dem zweiten Ende von jeder der Pleuelstangen in Eingriff zu kommen, um eine Winkelauslenkung von jeder der Pleuelstangen während einer Bewegung der sich hin und her bewegenden Kolbenanordnung über den abwärts gerichteten Leistungshub und den aufwärts gerichteten umgekehrten Auslasshub zu begrenzen.

3. Motor nach Anspruch 1, der weiter einen Nockenfolgevorrichtungsführungsring aufweist, der den mittleren Bereich umgibt und so strukturiert und angeordnet ist, dass die federgetriebenen Nockenfolgevorrichtungen in einer radial beabstandeten Anordnung um den mittleren Bereich gehalten werden.

4. Motor nach Anspruch 1, wobei die Ventilhubvorrichtung eine im Allgemeinen dreieckige Ausformung an dem ersten Ende von jeder der Pleuelstangen aufweist, und wobei die im Allgemeinen dreieckige Ausformung eine Spitze zum Eingriff mit der Membranventilklappe und zum Bewegen der Membranventilklappe in die offene Position aufweist, wenn der Kolben sich einem oberen Teil des aufwärts gerichteten umgekehrten Auslasshubes nähert.

Revendications

1. Moteur comprenant :

une pluralité de cylindres agencés en configuration radiale entourant une région centrale, et chacun des cylindres comportant un ensemble piston alternatif qui est mobile fonctionnellement entre une course de travail vers le bas et une course d'échappement revenant vers le haut, et chaque ensemble piston comprenant un piston disposé de façon mobile dans le cylindre et une bielle de connexion liée de façon pivotante au piston au niveau d'une première extrémité et s'étendant à partir du cylindre et se terminant au niveau d'une deuxième extrémité opposée dans la région centrale ;

un vilebrequin s'étendant axialement à travers le moteur le long d'un axe de rotation central longitudinal et comprenant une portion d'extrémité supérieure et une portion d'extrémité inférieure et le vilebrequin pouvant tourner autour de l'axe longitudinal central ;

un disque de vilebrequin en liaison d'entraînement avec la portion d'extrémité supérieure du vilebrequin et mobile autour d'un axe pivot central du disque de vilebrequin qui est décalé par rapport à l'axe de rotation central du vilebrequin de telle sorte que le disque de vilebrequin se déplace dans un mouvement orbital autour de l'axe de rotation central lorsque le vilebrequin tourne ;

un ensemble de distribution de vapeur comprenant un distributeur pour recevoir une alimentation en vapeur et une pluralité d'ensembles de soupape d'admission de vapeur connectés au distributeur pour injecter de façon contrôlée de la vapeur sous pression dans les cylindres, et chacun de la pluralité d'ensembles de soupape d'admission de vapeur comprenant une soupape d'admission de vapeur au niveau de chacun de la pluralité de cylindres, et la soupape d'admission de vapeur au niveau de chaque cylindre comprenant un élément de soupape actionnable entre une position ouverte et une position fermée par rapport au siège de soupape, et un accès d'admission s'étendant entre le siège de soupape et l'intérieur du cylindre au-dessus du piston, et chacune des soupapes d'admission de vapeur comprenant en outre une tige de soupape s'étendant à partir de l'élément de soupape vers une extrémité intérieure, et comportant un suiveur de came sollicité par un ressort fixé dessus ;

un galet de came mobile autour d'un chemin circulaire lors de la rotation du disque de vilebrequin et du vilebrequin pour contacter séquentiellement les suiveurs de came sollicités par ressort sur les extrémités intérieures des tiges de soupape et solliciter momentanément l'élément de soupape pour l'éloigner du siège de soupape, ouvrant ainsi la soupape d'admission et permettant l'injection de la vapeur dans le cylindre afin de forcer le piston dans la course de travail vers le bas et déplacer le disque de vilebrequin dans le mouvement orbital, faisant ainsi tourner le vilebrequin ;

un clapet à lamelle fixé au sommet du piston dans chacun de la pluralité de cylindres et définissant une soupape d'échappement, et le clapet à lamelle étant mobile entre une position fermée contre le sommet du piston et une position ouverte définie par le clapet à lamelle au moins partiellement soulevé pour s'éloigner du sommet du piston ;

un leveur de soupape sur chacune des bielles de connexion, le leveur de soupape étant agencé et disposé de façon à contacter le clapet à lamelle lorsque le piston s'approche du haut de la course d'échappement revenant vers le haut, pour soulever et ouvrir ainsi le clapet à lamelle et laisser la vapeur présente dans une portion supérieure du cylindre s'échapper à travers le cylindre et dans la région centrale ;

un condenseur comprenant une chambre de condenseur communiquant avec la région centrale pour recevoir le flux d'échappement ;

un dispositif de soufflage agencé et disposé de façon à diriger un flux d'air de refroidissement sur la surface extérieure du condenseur, condensant ainsi en liquide la vapeur se trouvant dans le condenseur ;

une pompe entraînée fonctionnellement en rotation par le vilebrequin pour pomper le liquide dans le condenseur vers une source de génération de vapeur externe ; et

un dispositif générateur d'énergie électrique lié fonctionnellement au vilebrequin et actionné par la rotation du vilebrequin pour produire ainsi de l'énergie électrique.

2. Moteur selon la revendication 1, comprenant en outre :

des éléments d'oreilles faisant saillie à partir de côtés opposés de chacune des bielles de connexion sur la deuxième extrémité opposée ;

des broches de restriction sur le disque de vilebrequin pour contacter les éléments d'oreilles sur la deuxième extrémité des bielles de connexion pour limiter la déviation angulaire de chacune des bielles de connexion pendant un mouvement de l'ensemble piston alternatif dans la course de travail vers le bas et la course d'échappement revenant vers le haut.

3. Moteur selon la revendication 1, comprenant en outre :

une bague de guidage de suiveur de came entourant la région centrale et agencée et disposée pour maintenir les suiveurs de came sollicités par ressort dans un agencement espacé radialement autour de la région centrale.

4. Moteur selon la revendication 1, dans lequel le dispositif de levage de soupape comprend un élément généralement triangulaire formé sur la première extrémité de chaque bielle de connexion, et l'élément généralement triangulaire comprend un sommet pour contacter le clapet à lamelle et déplacer le clapet à lamelle vers la position ouverte lorsque le piston approche du sommet de la course d'échappement revenant vers le haut.

Drawing